A steering damper varies damping based upon the input source: the steering device or the ground contact parts. The device comprises a housing fixed on an attaching part that couples the steering device and the ground contact parts. A main chamber is partitioned into a first and second damping chamber and flow is at least partially controlled by a main valve unit. The opening area of the main valve unit is determined by a relative motion between the attaching part and the steering device.
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1. A device intended for a vehicle comprising:
a steering device rotatable about a steering axis for adjusting a direction of one or more part(s) of the vehicle that are arranged for ground contact;
a damping housing of a steering damper that encloses a main damping chamber that is adapted to contain hydraulic fluid and that is partitioned into a first damping chamber and a second damping chamber;
an attaching part that couples the steering device and the one or more part(s) arranged for ground contact; and
a steering damper, wherein the attaching part rotates with the steering device and with the damping housing, and wherein a main valve unit is configured to adjust a flow of hydraulic fluid between the first damping chamber and the second damping chamber of the steering damper, the main valve unit is mechanically coupled together with both the attaching part and the steering device in order to adjust the rotational damping of the steering device and wherein an amount of hydraulic fluid flowing through the main valve unit is determined by a relative movement between the attaching part and the steering device.
10. A device intended for a vehicle comprising:
a steering device rotatable about a steering axis for adjusting a direction of one or more part(s) of the vehicle that are arranged for ground contacting;
an attaching part that couples together the steering device and the one or more part(s) that are arranged for ground contact; and
a steering damper comprising a delimiting part that partitions a main damping chamber that is adapted to contain hydraulic fluid and that is partitioned into a first damping chamber and a second damping chamber, wherein the attaching part rotates with the steering device and with the delimiting part, wherein a main valve unit is configured to adjust a flow of hydraulic fluid between the first damping chamber and the second damping chamber of the steering damper, the main valve unit is mechanically coupled together with both the attaching part and the steering device in order to adjust the rotational damping of the steering device, and wherein an amount of hydraulic fluid flowing through the main valve unit is determined by a relative movement between the attaching part and the steering device.
34. A steering damper configured to be arranged in a vehicle comprising a steering device rotatable about a steering axis for adjusting the direction of the part(s) of the vehicle configured for contacting the ground and an attaching part that couples together the part(s) arranged for contacting ground with the steering device, the steering damper comprising:
a damping housing; and
a main damping chamber defined by the damping housing, the main damping chamber comprising hydraulic fluid and being partitioned into a first and a second damping chamber;
wherein the steering device is mechanically connectable to the attaching part to enable rotation of the attaching part with the steering device and with the damping housing, and wherein a main valve unit is configured to adjust a flow of hydraulic fluid between the first and second damping chambers in order to adjust the rotational damping of the steering device, wherein the main valve unit can be mechanically coupled with both the attaching part and the steering device, and wherein a relative movement between the attaching part and the steering device determines an amount of hydraulic fluid flowing through the main valve unit.
35. A steering damper configured to be arranged in a vehicle comprising a steering device rotatable about a steering axis for adjusting the direction of the part(s) of the vehicle configured for contacting the ground and an attaching part that couples together the part(s) arranged for contacting ground with the steering device, the steering damper comprising:
a damping housing; and
a main damping chamber defined by the damping housing, the main damping chamber comprising hydraulic fluid and being partitioned into a first and a second damping chamber by a delimiting part,
wherein the steering device is mechanically connectable to the attaching part to enable rotation of the attaching part with the steering device and with the delimiting part, and wherein a main valve unit is configured to adjust a flow of hydraulic fluid between the damping chambers in order to adjust the rotational damping of the steering device, wherein the main valve unit can be mechanically coupled together with both the attaching part and the steering device, and wherein a relative movement between the attaching part and the steering device when the steering damper is arranged in a vehicle determines an amount of hydraulic fluid flowing through the main valve unit.
36. A crown device configured to be arranged in a vehicle comprising a steering device rotatable about a steering axis for adjusting the direction of the part(s) of the vehicle configured for contacting the ground, the device comprising:
a steering damper having a damping housing that encloses a main damping chamber which comprises hydraulic fluid and is partitioned into a first damping chamber and a second damping chamber by a delimiting part that is disposed in the main damping chamber and moveable with respect to the damping housing;
an attaching part configured to couple together the part(s) configured for contacting the ground with the steering device when the crown device is arranged in the vehicle, wherein the attaching part is configured to rotate with the steering device when the crown device is arranged in the vehicle; and
a main valve unit configured to adjust a flow of hydraulic fluid between the damping chambers of the steering damper when the crown device is arranged in the vehicle, the main valve unit being coupled together with both the attaching part and the steering device in order to adjust the rotational damping of the steering device, and wherein the amount of hydraulic fluid flowing through the main valve unit is determined by a relative movement between the attaching part and the steering device.
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This application is a national stage application under 35 U.S.C. §371 of PCT Application No. PCT/EP2010/066932 designating the United States, filed Nov. 5, 2010. The PCT Application was published in English as WO 2011/054934 A1 on May 12, 2011 and is a continuation-in-part and claims the benefit of the earlier filing date of PCT Application No. PCT/EP2009/064774, filed Nov. 6, 2009. The contents of PCT Application No. PCT/EP2009/064774 and PCT Application No. PCT/EP2010/066932 including the publication WO 2011/054934 A1 are incorporated herein by reference in their entirety.
1. Field of the Invention
The present invention relates to an adjustable steering damper intended to be used on a two or four-wheeled vehicle having a steering device comprising a handlebar or a steering wheel rotatable about a steering axis. Preferably the vehicle is a motorcycle, a snowmobile or an ATV. The steering damper is mounted at the steering device and is also coupled together with the frame or chassis by means of an attaching device. The damper is composed of an outer housing in which a main chamber is arranged, the main chamber comprising hydraulic fluid. The main chamber is partitioned into two chambers, for example by means of a delimiting part that is either rotatable about a first end or laterally displaceable in the chamber. The flow of the hydraulic fluid between the chambers is adjusted by a main valve and enables an adjustable damping of the relative motion between the steering device and the frame/chassis.
2. Description of the Related Art
A steering damper is mounted between the rotating handlebar or steering wheel of a vehicle and its fixed frame or chassis in order to damp shocks and violent movements that propagate from the front wheel(s) to the handlebar. When the steering damper is used on a motorcycle, the steering damper can also solve the problem of wobbling that may occur in a motorcycle at high speeds. Wobbling refers to the front wheel on the motorcycle beginning to oscillate about the steering axis with increasing amplitude. When the steering damper is used on a four-wheeled terrain vehicle, a so called ATV, the steering damper is primarily intended to damp the rapid steering movements caused by, for example, an asymmetric load on the wheels.
It has proven to be a problem to separate desired steering movements from undesired shocks caused by unevenness of the ground in a steering damper. In order to not create a delay in the steering movement when the driver turns the handlebar, it is desirable that this desired rotational movement is undamped. At the same time, undesired rotational movements caused by shocks from the ground should be damped as much as possible to minimize the risk of the handlebar being stricken from the hands of the driver. Thus, it is desirable to provide a steering damper that actively adapts the damping based on the cause of the movement.
In EP1248013 the problem is solved by a steering damper that by means of electronics senses and controls the damping on the handlebar depending on whether the movement is caused by the driver or the ground.
A steering damper that solves this problem by means of a principally mechanical solution is not known.
It is with respect to the above considerations and others that the present invention has been made. The present invention seeks to mitigate, alleviate, or eliminate one or more of the above-mentioned deficiencies and disadvantages singly or in combination. In particular, the inventor has realized that it would be desirable to achieve a device that enables separating the damping in a steering damper of desired steering movements from undesired shocks caused by unevenness of the ground. The inventor has further realized that it would be desirable to achieve a device that enables separating the damping in a steering damper of desired steering movements from undesired shocks caused by unevenness of the ground in a manner that does not require electronic components.
It is also desirable that the damper obtains a damping characteristic that is the same for different individuals. Furthermore, the final product should be relatively inexpensive and uncomplicated to manufacture.
To achieve this, a device and a steering device having the features as defined in the independent claims are provided. Further advantageous embodiments of the present invention are defined in the dependent claims.
Certain embodiments provide a device for adjusting the rotational damping of a steering device in a vehicle such that the rotational damping varies depending on whether the rotational movement about a steering axis is caused by a force acting on the steering device of the vehicle or by a force acting on the part(s) of the vehicle contacting the ground. In a preferred embodiment, the steering device refers to the handlebar, steering wheel, or the like of the vehicle, and parts of the vehicle contacting the ground refer to wheels, runners or similar arrangements that constitute the vehicle's points of contact against the ground. Certain embodiments further relate to a steering device adapted to be arranged in a vehicle.
The device and steering device according to the present invention are for example intended to be used on a one, two, three or four-wheeled vehicle.
In certain embodiments of the present invention, there is provided a device intended for a vehicle. The device comprises a steering device rotatable about a steering axis for adjusting the direction of the part(s) of the vehicle arranged for contacting the ground, an attaching part that couples together the part(s) arranged for contacting the ground with the steering device, and a steering damper. The attaching part rotates with the steering device and with the damping housing of the steering damper that encloses a main damping chamber. The main damping chamber comprises hydraulic fluid and is partitioned into a first and a second damping chamber, wherein flow of hydraulic fluid between the damping chambers of the steering damper is adjusted by means of a main valve unit mechanically coupled together with both the attaching part and the steering device in order to adjust the rotational damping of the steering device. The amount of hydraulic fluid flowing through the main valve unit is determined by a relative movement between the attaching part and the steering device.
Certain embodiments of the present invention provide a device intended for a vehicle. The device comprises a steering device rotatable about a steering axis for adjusting the direction of the part(s) of the vehicle arranged for contacting the ground, an attaching part that couples together the part(s) arranged for contacting the ground with the steering device, and a steering damper. The attaching part rotates with the steering device and with a delimiting part of the steering damper that partitions a main damping chamber which comprises hydraulic fluid into a first and a second damping chamber, wherein flow of hydraulic fluid between the damping chambers of the steering damper is adjusted by means of a main valve unit mechanically coupled together with both the attaching part and the steering device in order to adjust the rotational damping of the steering device. The amount of hydraulic fluid flowing through the main valve unit is determined by a relative movement between the attaching part and the steering device. In other words, by means of the main valve unit being coupled together with both the attaching part and the steering device, an opening area of the main valve unit may be determined by a relative motion between the attaching part and the steering device such that the flow of the hydraulic fluid in a direction from and to the respective damping chamber of the steering damper is controlled depending on the cause of the rotational movement. Such a configuration may enable means for adjusting the rotational damping of a steering device in a vehicle such that the rotational damping varies depending on whether the rotational movement about the steering axis is caused by a force acting on the steering device of the vehicle or by a force acting on the part(s) of the vehicle contacting the ground. In other words, the device of the present invention may enable separating the damping in a steering damper of desired steering movements from undesired shocks caused by unevenness of the ground. This may be achieved by means of a substantially or completely mechanical arrangement. Thus, electronic components may not be required for achieving advantages of the present invention.
Other embodiments of the invention provide a device intended for a vehicle comprising: a steering device rotatable about a steering axis for adjusting the direction of the part(s) of the vehicle arranged for contacting the ground; a steering damper comprising a damping housing that encloses a main damping chamber which comprises hydraulic fluid and is partitioned into a first damping chamber and a second damping chamber by a delimiting part that is arranged in the main damping chamber and movable with respect to the damping housing; an attaching part that couples together the part(s) arranged for contacting the ground with the steering device and a steering damper, wherein the attaching part rotates with the steering device and any one of the damping housing and the delimiting part; and a main valve unit (HVU) adapted to adjust a flow of hydraulic fluid between the damping chambers of the steering damper. The main valve unit (HVU) is mechanically coupled together with both the attaching part and the steering device in order to adjust the rotational damping of the steering device, wherein the amount of hydraulic fluid flowing through the main valve unit (HVU) is determined by a relative movement between said attaching part and the steering device.
Certain embodiments of the invention provide a steering damper adapted to be arranged in a vehicle comprising a steering device rotatable about a steering axis for adjusting the direction of the part(s) of the vehicle arranged for contacting the ground and an attaching part that couples together the part(s) arranged for contacting the ground with the steering device. The steering damper comprises a damping housing and a main damping chamber defined by the damping housing. The main damping chamber comprises hydraulic fluid and is partitioned into a first and a second damping chamber. The steering device is mechanically connectable to the attaching part to enable rotation of the attaching part with the steering device and with the damping housing. A main valve unit is adapted to adjust a flow of hydraulic fluid between the damping chambers in order to adjust the rotational damping of the steering device, wherein the main valve unit can be mechanically coupled together with both the attaching part and the steering device. The steering damper is configured such that a relative movement between the attaching part and the steering device determines an amount of hydraulic fluid flowing through the main valve unit.
Certain embodiments of the invention provide a steering damper adapted to be arranged in a vehicle comprising a steering device rotatable about a steering axis for adjusting the direction of the part(s) of the vehicle arranged for contacting the ground and an attaching part that couples together the part(s) arranged for contacting the ground with the steering device. The steering damper comprises a damping housing and a main damping chamber defined by the damping housing. The main damping chamber comprises hydraulic fluid and is partitioned into a first and a second damping chamber by a delimiting part. The steering device is mechanically connectable to the attaching part to enable rotation of the attaching part with the steering device and with the delimiting part. A main valve unit is adapted to adjust a flow of hydraulic fluid between the damping chambers in order to adjust the rotational damping of the steering device, wherein the main valve unit can be mechanically coupled together with both the attaching part and the steering device. The steering damper is configured such that a relative movement between the attaching part and the steering device determines an amount of hydraulic fluid flowing through the main valve unit. In this manner, the amount of hydraulic fluid flowing through the main valve unit is determined by a relative movement between the attaching part and the steering device. Thus, according to an aspect of the invention, there is provided a steering damper adapted to be arranged in a vehicle comprising a steering device rotatable about a steering axis (SA) for adjusting the direction of the part(s) of the vehicle arranged for contacting the ground and an attaching part that couples together the part(s) arranged for contacting the ground with the steering device. The steering damper comprises a main damping chamber defined by a damping housing, said main damping chamber comprising hydraulic fluid and partitioned into a first and a second damping chamber. The steering device is mechanically connectable to said attaching part to enable rotation of said attaching part with said steering device and with any one of said damping housing and said delimiting part. A main valve unit (HVU) is adapted to adjust a flow of hydraulic fluid between the damping chambers in order to adjust the rotational damping of the steering device, wherein said main valve unit (HVU) can be mechanically coupled together with both the attaching part and the steering device, and wherein a relative movement between said attaching part and the steering device determines an amount of hydraulic fluid flowing through the main valve unit (HVU).
In some embodiments, the main damping chamber being defined by the damping housing may for example refer to an arrangement wherein the damping housing encloses the main damping chamber.
The main valve unit may be arranged integral with the steering device.
In certain embodiments, the steering device may be elastically coupled together with the attaching part. The relative movement between the attaching part and the steering device may, according to one example, occur only during a predetermined initial rotational movement of the steering device from a base position of the steering device.
It is understood that relative rotational movement between the attaching part and the steering device refers to relative movement about the steering axis or about another axis substantially parallel to the steering axis. The main valve unit may comprise a first and a second main valve.
In one embodiment, the device or the steering device may comprise a first main valve part and a second main valve part arranged in the first main valve and a third main valve part and a fourth main valve part arranged in the second main valve. The first main valve part may be coupled together with the steering device and the second main valve part may be coupled together with the damping housing of the steering damper. The third main valve part may be coupled together with the steering device and the fourth main valve part may be coupled together with the damping housing of the steering damper. The first and the second, and the third and the fourth main valve parts, respectively, may be moveable with respect to each other such that they form a first and a second variable opening area through which the hydraulic fluid can flow.
The opening area of the first main valve may decrease and the opening area of the second main valve may increase when the positions of the first and the second, and the third and the fourth main valve parts, respectively, relative to each other, are determined by a rotational motion in a first direction of the steering device or by a rotational motion in a second direction of the housing of the steering device.
The opening area of the first main valve may increase and the opening area of the second main valve may decrease when the positions of the first and the second, and the third and the fourth main valve parts, respectively, relative to each other, are determined by a rotational motion in a second direction of the steering device or by a rotational motion in a first direction of the housing of the steering device.
The opening area of the first main valve may increase and the opening area of the second main valve may decrease when the positions of the first and the second, and the third and the fourth main valve parts, respectively, relative to each other, are determined by a rotational motion in a second direction of the steering device or by a rotational motion in a first direction of the delimiting part of the steering damper.
The first and third main valve parts of the first and second main valve may move synchronously in relation to each other such that the opening area of the first main valve decreases substantially as much as the opening area of the second main valve increases, and vice versa.
The device or the steering device may comprise a first driver and a second driver, wherein the first main valve part may be coupled together with the steering device via the first driver and the third main valve part may be coupled together with the steering device via the second driver.
The first driver may be coupled together with the first main valve part by means of a first link and the second driver may be coupled together with the third main valve part by means of a second link, where the links are hinged at both ends.
The device or the steering device may comprise at least one spring element, wherein the first driver may be pressed against the first main valve part and the second driver may be pressed against the third main valve part by means of the at least one spring element.
The at least one spring element may be located between the first main valve part and the third main valve part such that the at least one spring element creates a pressing force acting on both valve parts.
In some embodiments, the device may furthermore comprise a valve actuator coupled together with the steering device for actuating the first and second main valves during relative movement between the steering device and the attaching part, thereby altering a first and a second variable opening area of the main valve. In other words, the valve actuator is moved in response to movement of the steering device when the valve actuator is coupled to the steering device. The valve actuator may refer to a pin, dowel, bolt or the like. The valve actuator may be coupled to the steering device by means of direct connection or may be coupled to the steering device via an intermediate element which may be attachment means arranged for clamping the steering device to the attaching part. The valve actuator may also refer to an extending portion of the steering device or an extending portion of the intermediate element being coupled to the steering device. Put differently, the valve actuator may be a mechanical element intended to affect the main valve unit upon relative movement between the steering device and the attaching part, i.e. when the steering device is turned or when the attaching part is rotated by force acting on the part(s) of the vehicle contacting the ground.
The device may furthermore comprise a valve actuator coupled together with the attaching part for actuating the first and second main valves during relative movement between the steering device and the attaching part, thereby altering a first and a second variable opening area of the main valve. In other words, the valve actuator is moved in response to movement of the attaching part when the valve actuator is coupled to the attaching part.
Put differently, the valve actuator may be a mechanical element intended to affect the main valve unit, in the sense that the hydraulic fluid flowing through the main valve unit is affected, upon relative movement between the steering device and the attaching part, i.e. when the steering device is turned or when the attaching part is rotated by force acting on the part(s) of the vehicle contacting the ground.
The opening area of the first main valve may decrease and the opening area of the second main valve may increase when the position of the valve actuator is determined by a rotational motion in a first direction of the steering device or by a rotational motion in a second direction of the attaching part. In other words, when the steering device is rotated in a first direction or when the attaching part is rotated in the opposite direction, the opening area of the first valve may decrease and the opening area of the second valve may increase.
The opening area of the first main valve may increase and the opening area of the second main valve may decrease when the position of the valve actuator is determined by a rotational motion in a second direction of the steering device or by a rotational motion in a first direction of the attaching part. In other words, when the steering device is rotated in a second direction or when the attaching part is rotated in the opposite direction, the opening area of the first valve may increase and the opening area of the second valve may decrease. The device or the steering device may comprise at least one holding-up means arranged between the attaching part and the steering device, the at least one holding-up means configured to determine the magnitude of the initial rotational motion.
The steering device may be coupled together with the attaching part via a torsion bar for allowing relative rotational movement between the steering device and the attaching part about a central axis of the torsion bar. It is understood that torsion bar refers to a metal element being substantially elastically twistable and that acts as a spring. The torsion bar may be arranged in parallel to the steering axis.
The central axis of the torsion bar may be arranged at a distance from the steering axis. In other words, the steering device rotates relative to the attaching part about the central axis of the torsion bar which is arranged at a distance from the steering axis.
The device may furthermore comprise at least two mechanical stops for limiting said relative movement between the attaching part and the steering device. Hereby it may be possible to avoid excessive rotational movement between the steering device and the attaching part which otherwise could result in a damages to the torsion bar. The two mechanical stops may refer to two mechanical elements such as two pins extending from the attaching part, thereby limiting the relative rotational movement. In other embodiments, the two mechanical stops may refer to mechanical devices involving at least two parts. The mechanical stops may interact with other portions of the attaching part or the steering device. The mechanical stops may refer to portions of an intermediate element such as attaching means for clamping the steering wheel to the attaching part.
The two mechanical stops may comprise at least one element slideably arranged in an opening between two surface portions thereof, such that the element is moveable between said surface portions in order to limit said relative movement to rotational movement. Therefore it may be possible to avoid damaging the torsion bar if, for example, force is applied to the steering device in directions other than the rotational direction. One such case may be during a motorcycle crash or during rough offroad driving. In one embodiment, an element is attached to one of the steering device and the attaching part and an opening is arranged in the other one of the steering device and the attaching part, in which opening the element is slideably arranged. The opening may be a hole, a slot, an aperture or the like. The opening may have dimensions relative to the element to achieve a play such that slideable operation is achieved. The element may have geometric properties such that axial relative movement between the steering device and the attaching part is limited. For example, the element may be shaped substantially as a bolt or screw, i.e. having a larger diameter in its one end. The attaching part may for example comprise a fork crown arranged at the front fork arrangement of a motorcycle.
The attaching part may comprise a cylindrical unit arranged around a steering connecting rod through which the steering axis runs.
The attaching part may be divided into an upper and a lower cylindrical part coupled together by means of an elastic holding-up means that is arranged to determine the magnitude of the initial rotational motion.
The device or the steering device may comprise a delimiting part arranged in the main damping chamber, in which the delimiting part is moveable with respect to the damping housing.
The steering damper may be a linear damping device in which the delimiting part is a piston attached to a piston rod for reciprocal movement within said damping chamber. The steering damper may be arranged at least partly inside the attaching part for achieving a compact installation. The piston rod may be hollow in order to achieve hydraulic fluid flow passages to the damping chambers.
The steering damper may be a rotational damping device, in which the delimiting part is a wing attached to a lever for reciprocal movement within said damping chamber. It is understood that lever refers to a mechanical element arranged for transferring rotational force to and from the wing. The rotational damping device may be of the type commonly referred to as a wing damper.
According to another embodiment of the present invention, there is provided a crown device adapted to be arranged in a vehicle comprising a steering device rotatable about a steering axis for adjusting the direction of the part(s) of the vehicle arranged for contacting the ground. The crown device comprises a steering damper, an attaching part and a main valve unit. The steering damper comprises a damping housing that encloses a main damping chamber which comprises hydraulic fluid and is partitioned into a first damping chamber and a second damping chamber by a delimiting part that is arranged in the main damping chamber and moveable with respect to the damping housing. The attaching part is adapted to couple together the part(s) arranged for contacting the ground with the steering device when the crown device is arranged in the vehicle. The attaching part is arranged to rotate with the steering device when the crown device is arranged in the vehicle. The main valve unit that is adapted to adjust a flow of hydraulic fluid between the damping chambers of the steering damper when the crown device is arranged in the vehicle. The main valve unit is coupled together with both the attaching part and the steering device when the crown device is arranged in the vehicle in order to adjust the rotational damping of the steering device. The amount of hydraulic fluid flowing through the main valve unit is determined by a relative movement between the attaching part and the steering device.
Thus, a relative movement is provided by allowing the steering device to move relative to the attaching part. Furthermore, by monitoring or measuring that relative movement between the steering device and the attaching part, the rotational damping of a steering device is adjustable such that the rotational damping varies depending on whether the rotational movement about a steering axis is caused by a force acting on the steering device of the vehicle or by a force acting on the part(s) of the vehicle contacting the ground.
The crown device may comprise attachment means adapted to couple the steering device together with the attaching part when the crown device is arranged in the vehicle, wherein the attachment means is arranged to allow relative movement between the attaching part and the steering device when the crown device is arranged in the vehicle. In other words, the attachment means may be an intermediate element between the attaching part and the steering device allowing relative movement between the attaching part and the steering device. Relative movement may be realized between the attaching part and the attachment means, i.e. when the steering device is fixed to the attachment means. Alternatively, relative movement may be realized between the steering device and the attachment means, i.e. when the attaching part is fixed to the attachment means.
The attachment means may be adapted to elastically couple the steering device together with the attaching part when the crown device is arranged in the vehicle, wherein the attachment means is arranged to elastically allow relative movement between the attaching part and the steering device when the crown device is arranged in the vehicle.
The main valve unit may be mechanically coupled together with both the attaching part and the steering device in order to adjust the rotational damping of the steering device. Thus, a mechanical crown device may be achieved which may not require electronics to achieve actuation of the main valve unit.
The crown device may furthermore comprise an electronic sensor adapted to measure said relative movement between the attaching part and the steering device. Thus, the relative movement may be measured electronically and the steering damper may be controlled in a customized manner by, for example, an electronic control unit (ECU). Using an electronic sensor may also be advantageous when compared to a mechanical actuating mechanism from a friction perspective.
The electronic sensor may be selected from a group of sensors comprising a potentiometer, a hall effect sensor, and an optical sensor.
The electronic sensor may be arranged to measure the magnitude and the direction of the relative movement between the attaching part and the steering device when the crown device is arranged in the vehicle. This may be advantageous because the additional information provided by the electronic sensor, i.e. magnitude and direction, may be used to achieve improved control of the steering damper. Further objects and advantages of the various embodiments of the present invention will be described below by means of exemplifying embodiments.
Exemplifying embodiments of the invention will be described below with reference to the accompanying drawings, in which:
In the accompanying drawings, the same reference numerals denote the same or similar elements throughout the views.
The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which exemplifying embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided by way of example so that this disclosure will convey the scope of the invention to those skilled in the art. Furthermore, like numbers refer to like or similar elements throughout.
Another embodiment of the invention may include three wheels on this type of vehicle. The joining of the front fork legs 3a of the motorcycle and the motorcycle frame's front chassis 6 takes place by means of one or several attaching parts 5 which in this case have the shape of fork crowns 5a, 5b. The fork crowns 5a, 5b are rotatable about a steering axis SA centered in a steering column 6 extending through both of the fork crowns 5a, 5b. The front wheel (not shown) of the motorcycle is located between the right fork leg and the symmetrically located left fork leg 3a such that rotation of front wheel, fork crowns 5a, 5b and fork legs 3a takes place about the steering axis SA. A steering device in the form of a handlebar 2 is attached in the upper fork crown 5a by means of a first 7a and second 7b attachment means. The attachment means 7a, 7b comprise two parts; an upper 7a1, 7b1 and a lower 7a2, 7b2, between which the handlebar 2 is clamped.
In addition to a handlebar, a steering wheel may also be used as steering device 2 for adjusting the direction of the vehicle's part(s) 3 contacting the ground. In
In
In
The holding-up means 10a, 10b can also be constructed such that they are more elastic when rotated compared to when bent. The holding-up means 10a, 10b can in that case be arranged in the attachment means in the manner shown in
Additional embodiments of a steering damper having an inner moveable delimiting part 11 are described in more detail in
In both embodiments shown in
The valve arrangement 15 is shown in detail in
The first main valve comprises a first main valve part 17a and a second main valve part 17b. The first main valve part 17a is closely coupled together with the steering device 2 via a first link 19a to the first driver 8a and the second main valve part 17b is closely coupled together with the attaching part 5 via the damping housing 4a of the steering damper. The second main valve comprises a third main valve part 18a and a fourth main valve part 18b. The third main valve part 18a is, via a second link, closely coupled together with the steering device by means of the second driver 8b and the fourth main valve part 18b is closely coupled together with the attaching part 5 via the damping housing 4a of the steering damper. The first and the second main valve parts 17a, 17b and the third and the fourth main valve parts 18a, 18b, respectively, move relative to each other during the initial rotational movement. This creates a first and a second variable opening area A1, A2 through which the hydraulic fluid can flow when a pressure difference between the damping chambers C1, C2 is present and when no disturbance acts in a direction that is reverse to the intentional rotational movement of the steering means. By means of coordinated effect on the main valves' first and third valve parts 17a, 18a by respective adjustment devices, the opening area A1 of the first main valve 17 decreases while the opening area A2 of the second main valve 18 at the same time increases, and vice versa. An adjustment in the opening area results in that control of the flow of hydraulic fluid from and to the respective damping chamber C1, C2 of the steering damper is enabled and eventually completely flowing freely or being brought to a stop when the initial rotation has been finished.
In
In
When the first and the second main valves 17, 18, respectively, are open, i.e. when the turning motion of the handlebar is caused by the driver, the hydraulic fluid basically flows freely between the damping chambers with no restriction and no damping of the steering motion takes place but the vehicle reacts just as quickly as if no steering damper were mounted. If a certain amount of damping is also desired when steering it may be achieved by an adjustment of the position of the first and second main valve parts 17a, 17b; 18a, 18b relative to each other. When shocks and impacts causes the wheel to be turned against the driver's will the motion of the handlebar is blocked or strongly damped in the undesired turning direction as the main valves 17, 18 in that direction are closed and the flow between the damping chambers is prevented.
In summary, a device is disclosed for adjusting the rotational damping of a steering device in a vehicle such that the rotational damping varies depending on whether the rotational motion about a steering axis is caused by a force acting on the steering device of the vehicle or a force acting on the part(s) of the vehicle contacting the ground. The device comprises a steering damper comprising a damping housing enclosing a main chamber which comprises hydraulic fluid and is partitioned into a first and a second damping chamber, for example by a delimiting part moveable in relation to the damping housing. The damping housing is fixed on an attaching part that couples together the part(s) of the vehicle contacting the ground with the steering device. The present invention is characterized in that the flow of hydraulic fluid in the steering damper partly or wholly is adjusted by a main valve unit that is coupled together with both the attaching part and the steering device. By means of this coupling the opening area of the main valve unit is determined by a relative motion between the attaching part and the steering device such that the flow of the hydraulic fluid in a direction from and to the respective damping chamber of the steering damper is controlled depending on the cause of the rotational movement.
Although exemplary embodiments of the present invention have been described herein, it should be apparent to those having ordinary skill in the art that a number of changes, modifications or alterations to the invention as described herein may be made. Thus, the above description of the various embodiments of the present invention and the accompanying drawings are to be regarded as non-limiting examples of the invention and the scope of protection is defined by the appended claims. Any reference signs in the claims should not be construed as limiting the scope.
Nilsson, Johan, Gustafsson, Leif, Sintorn, Torkel, Hansen, Thorleif, Mattison, Joakim
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Nov 05 2010 | Ohlins Racing AB | (assignment on the face of the patent) | / | |||
Mar 20 2013 | HANSEN, THORLEIF | Ohlins Racing AB | CORRECTIVE ASSIGNMENT TO CORRECT THE APPLICATION NUMBER FROM 12 508,330 TO 13 508,330 PREVIOUSLY RECORDED ON REEL 030062 FRAME 0247 ASSIGNOR S HEREBY CONFIRMS THE CORRECT APPLICATION NUMBER | 030757 | /0647 | |
Mar 20 2013 | GUSTAFSSON, LEIF | Ohlins Racing AB | CORRECTIVE ASSIGNMENT TO CORRECT THE APPLICATION NUMBER FROM 12 508,330 TO 13 508,330 PREVIOUSLY RECORDED ON REEL 030062 FRAME 0247 ASSIGNOR S HEREBY CONFIRMS THE CORRECT APPLICATION NUMBER | 030757 | /0647 | |
Mar 20 2013 | NILSSON, JOHAN | Ohlins Racing AB | CORRECTIVE ASSIGNMENT TO CORRECT THE APPLICATION NUMBER FROM 12 508,330 TO 13 508,330 PREVIOUSLY RECORDED ON REEL 030062 FRAME 0247 ASSIGNOR S HEREBY CONFIRMS THE CORRECT APPLICATION NUMBER | 030757 | /0647 | |
Mar 20 2013 | SINTOM, TORKEL | Ohlins Racing AB | CORRECTIVE ASSIGNMENT TO CORRECT THE APPLICATION NUMBER FROM 12 508,330 TO 13 508,330 PREVIOUSLY RECORDED ON REEL 030062 FRAME 0247 ASSIGNOR S HEREBY CONFIRMS THE CORRECT APPLICATION NUMBER | 030757 | /0647 | |
Mar 20 2013 | MATTISON, JOAKIM | Ohlins Racing AB | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 030062 | /0247 | |
Mar 20 2013 | HANSEN, THORLEIF | Ohlins Racing AB | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 030062 | /0247 | |
Mar 20 2013 | GUSTAFSSON, LEIF | Ohlins Racing AB | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 030062 | /0247 | |
Mar 20 2013 | NILSSON, JOHAN | Ohlins Racing AB | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 030062 | /0247 | |
Mar 20 2013 | SINTORN, TORKEL | Ohlins Racing AB | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 030062 | /0247 | |
Mar 20 2013 | MATTISON, JOAKIM | Ohlins Racing AB | CORRECTIVE ASSIGNMENT TO CORRECT THE APPLICATION NUMBER FROM 12 508,330 TO 13 508,330 PREVIOUSLY RECORDED ON REEL 030062 FRAME 0247 ASSIGNOR S HEREBY CONFIRMS THE CORRECT APPLICATION NUMBER | 030757 | /0647 |
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